Hinge device

What is claimed is: 1. A hinge device comprising: first and second hinge bodies ( 10 , 20 ), first and second arms ( 30 , 40 ) arranged between the first and second hinge bodies, a first shaft member ( 51 ) that rotatably connects one end of the first arm to the first hinge body, a second shaft member ( 52 ) that rotatably connects one end of the second arm to the second hinge body and an intermediate shaft member ( 50 ) that rotatably connects intermediate portions of the first and second arms, wherein a first guide ( 15 ; 15 ′; 100 ) having a main guide portion ( 15 x ; 15 x ′; 101 ) extending in a direction approaching or separating from the first shaft member is formed on the first hinge body and the other end of the second arm is slidably and rotatably guided to the first guide, wherein a second guide ( 25 ) extending in a direction approaching or separating from the second shaft member is formed on the second hinge body and the other end of the first arm is slidably and rotatably guided to the second guide, wherein the hinge device further comprises a friction resistance generation mechanism ( 60 , 61 ) that provides frictional resistance against a relative rotation of the first and second arms around the intermediate shaft member and eventually provides friction torque against a relative rotation of the second hinge body with respect to the first hinge body, wherein the first hinge body is provided with an energizing member ( 70 , 80 ) that applies rotation torque toward a rotation limit position to the second hinge body by energizing the first arm, wherein the first guide ( 15 ; 15 ; 100 ) further has a sub-guide portion ( 15 y ; 15 y′; 102 ) connected to one end of the main guide portion, and wherein in the process in which the second hinge body rotates relative to the first hinge body over a specific angle range from the rotation limit position, the other end of the second arm ( 20 ) moves along the sub-guide portion ( 15 y ; 15 y ′; 102 ) and the sub-guide portion is formed so as to allow the other end of the second arm to move along an arc centered on the first shaft member ( 51 ). 2. The hinge device as claimed in claim 1 , wherein the first hinge body ( 10 ) has first guide grooves ( 15 ; 15 ′; 100 ) as the first guide, and each of the first guide grooves has a main groove portion ( 15 x ; 15 x ′; 101 ) as the main guide portion and a sub-groove portion ( 15 y ; 15 y ′; 102 ) as the sub-guide portion, wherein the second hinge body ( 20 ) has second guide grooves ( 25 ) as the second guide, and wherein a first protrusion having a circular cross section inserted into the second guide grooves is formed at the other end of the first arm ( 30 ), and a second protrusion having a circular cross section inserted into the first guide grooves is formed at the other end of the second arm. 3. The hinge device as claimed in claim 2 , wherein the first hinge body ( 10 ) and the second hinge body ( 20 ) each have a base wall ( 11 , 21 ) and a pair of side walls ( 12 , 22 ) that are orthogonal to the base wall and parallel to each other, the first guide grooves ( 15 ; 15 ′; 100 ) having the same shape are formed respectively on the pair of side walls of the first hinge body, and the second guide grooves ( 25 ) having the same shape are formed respectively on the pair of side walls of the second hinge body, wherein each of both ends of a first slide pin ( 55 ) which passes through and is supported by the other end of the first arm ( 30 ) is provided as the first protrusion, and wherein each of both ends of a second slide pin ( 56 ) which passes through and is supported by the other end of the second arm ( 40 ) is provided as the second protrusion. 4. The hinge device as claimed in claim 2 , wherein the sub-groove portion ( 102 ) of each of the first guide grooves ( 100 ) has an inner edge ( 102 a ) close to the first shaft member ( 51 ) and an outer edge ( 102 b ) away from the first shaft member ( 51 ), and wherein in the process of the second hinge body ( 20 ) moving toward the rotation limit position in the specific angle range, and the second protrusion moves along the sub-groove portion without making contact with either the inner edge or the outer edge of the sub-groove portion. 5. The hinge device as claimed in claim 4 , wherein the inner edge ( 102 a ) of the sub-groove portion ( 102 ) is deviated so as to be closer to the first shaft member than a virtual line (L) that draws the arc centered on the first shaft member ( 51 ) from a point (Pa) inside an intersection ( 103 ) of the main groove portion ( 101 ) and the sub-groove portion ( 102 ). 6. The hinge device as claimed in claim 1 , wherein the energizing member consists of a torsion spring ( 80 ), and the torsion spring ( 80 ) has a locking portion ( 80 b ) that is locked to the first hinge body ( 10 ) and a pressing portion ( 80 c ), and wherein a receiving surface ( 31 c ) is formed at the one end of the first arm ( 30 ), and when the second hinge body ( 20 ) is in a predetermined torque applying angle range, the pressing portion of the torsion spring pushes the receiving surface. 7. The hinge device as claimed in claim 6 , wherein the first hinge body ( 10 ) and the second hinge body ( 20 ) each have a base wall ( 11 , 21 ) and a pair of side walls ( 12 , 22 ) that are orthogonal to the base wall and parallel to each other, first guide grooves ( 15 ; 15 ′; 100 ) having the same shape as the first guide are formed respectively on the pair of side walls of the first hinge body, second guide grooves ( 25 ) having the same shape as the second guide are formed respectively on the pair of side walls of the second hinge body, a second protrusion protruding from the other end of the second arm ( 40 ) is inserted into the first guide grooves, and a first protrusion protruding from the other end of the first arm ( 30 ) is inserted into the second guide grooves, and wherein an elongated hole ( 19 ) is formed in the pair of side walls of the first hinge body, both ends of a pressing pin ( 82 ) are slidably inserted in the elongated hole along the elongated hole, and when the second hinge body is in the torque applying angle range, the pressing portion of the torsion spring pushes the receiving surface ( 31 c ) of the first arm via the pressing pin. 8. The hinge device as claimed in claim 1 , wherein the energizing member consists of a leaf spring ( 70 ), both ends of the leaf spring are supported by the first hinge body ( 10 ), and a middle portion of the leaf spring is provided as a pressing portion ( 70 a ) protruding toward one end of the first arm, and wherein a receiving surface ( 31 y ) is formed at the one end of the first arm, and when the second hinge body ( 20 ) is in a predetermined torque applying angle range, the pressing portion of the leaf spring pushes the receiving surface. 9. The hinge device as claimed in claim 8 , wherein the first hinge body ( 10 ) and the second hinge body ( 20 ) each have a base wall ( 11 , 21 ) and a pair of side walls ( 12 , 22 ) that are orthogonal to the base wall and parallel to each other, first guide grooves ( 15 ; 15 ′; 100 ) having the same shape as the first guide are formed respectively on the pair of side walls of the first hinge body, second guide grooves ( 25 ) having the same shape as the second guide are formed respectively on the pair of side walls of the second hinge body, a second protrusion protruding from the other end of the second arm is inserted into the first guide grooves, and a first protrusion protruding from the other end of the first arm is inserted into the second guide grooves, and wherein the leaf spring has both ends curved in an arc